Ultralow loss torsion micropendula for chipscale gravimetry
Abstract
We explore a new class of chipscale torsion pendula formed by Si3N4 nanoribbon suspensions. Owing to their unique hierarchy of gravitational, tensile, and elastic stiffness, the devices exhibit damping rates of 10\;μHz and parametric gravity sensitivities near that of an ideal pendulum. The suspension nonlinearity can also be used to cancel the pendulum nonlinearity, paving the way towards fully isochronous, high Q pendulum gravimeters. As a demonstration, we study a 0.1 mg, 32 Hz micropendulum with a damping rate of 16\;μHz, a thermal acceleration sensitivity of 2\;ng/Hz, and a parametric gravity sensitivity of 5 Hz/g0. We record Allan deviations as low as 2.5 μHz at 100 seconds, corresponding to a bias stability of 5× 10-7g0. We also demonstrate a 100-fold cancellation of the pendulum nonlinearity. In addition to inertial sensing, our devices are well suited to proposed searches for new physics exploiting low-loss micro- to milligram-scale mechanical oscillators.
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